KR20000071630A - Double damper device - Google Patents

Abstract

It prevents the leakage of cold air that is likely to occur when weaving it together with the insulation member in the refrigerator duct, that is, the leakage (flow) of cold air from one flow path to the other flow path, and as a result, the energy efficiency of each chamber passing through each opening is good. To provide a double damper device that can be cold and easy to manage the temperature of each room.

As a means to solve this problem, the drive unit 2, two cylindrical frame units 3 and 4 disposed on both sides with the drive unit 2 interposed therebetween, and the drive unit 2 connected to the drive unit 2 To the double damper device 1 having two opening / closing members 5 and 6 which operate to open and close the openings 31 and 41 respectively formed in the respective frame portions 3 and 4 by the driving force of The step β is formed between the flat portions 37b and 47b of the two frame portions 3 and 4, and the so-called labyrinth structure is formed between the flat portions 37b and 47b. It is a structure which prevents the leakage of the fluid between two flow paths.

Description

Double Damper Device {DOUBLE DAMPER DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a double damper device which uses a motor or the like as a driving source and operates an opening / closing plate such as baffle for two openings, and more particularly, to a double damper device suitable for controlling cold air inlet in a refrigerator.

On the back side of the refrigerator or the like, a duct (path) for discharging the cold air in the freezer to the refrigerating chamber or the vegetable compartment is arranged. And conventionally, in the duct, a damper device for distributing / blocking the cold air of the refrigerating compartment to the refrigerating compartment and the like is disposed in order to control the temperature of the room such as the refrigerating compartment. Moreover, the double damper apparatus which can distribute | circulate / block cold air to two rooms by one apparatus is also conventionally disclosed (refer Unexamined-Japanese-Patent No. 10-306970). These damper devices are driven by control by a microcomputer arranged in a refrigerator.

The double damper device disclosed in Japanese Patent Laid-Open No. 10-306970, which is a prior art, includes a driving unit 51 in which a motor (not shown) is built, as shown in FIGS. 8 and 9, and disposed on both sides of the driving unit 51. Two frame parts 52 and 53 and two opening and closing members 54 and 55 connected to the driving part 51 and rotated by the driving force of the driving part 51 are provided. In addition, each of the frame portions 52 and 53 is provided with openings 56 and 57 serving as inlets of flow paths to different chambers (for example, a refrigerator compartment and a vegetable compartment). One opening / closing member 54 opens and closes the opening 56, and the other opening / closing member 55 opens and closes the opening 57 in a separate operation, respectively, to distribute / block cold air to each chamber.

In the double damper device configured as described above, the outer frame portion is closely fitted to the hole formed in the heat insulating member 60, and the heat insulating member 60 is disposed in the refrigerator by being fitted in the duct (not shown) of the refrigerator. That is, the double damper device is fitted to block the duct like the heat insulating member 60. The two openings 56 and 57 described above pass through a passage communicating from one side to another through a duct communicating from one side to the freezing chamber.

However, a slight loosening of the double damper device incorporated in each flow path into the above-described heat insulating member 60 results in poor sealing in the contact portion α (see FIG. 9) with the heat insulating member 60. That is, since the heat insulating member 60 is formed of foamed styrol or the like, the size of the hole for inserting the double damper cannot be made so precise that a gap g is generated between the double damper device and the heat insulating member 60. This gap g connects the two flow paths linearly, and since cold air on one flow path tends to leak to the other flow path side (X, X 'direction in FIG. 8), it causes trouble in temperature control of each chamber. Done.

An object of the present invention is to prevent the leakage of cold air, ie leakage of cold air from one flow path to the other flow path, which is likely to occur when incorporated together with a heat insulating member in a duct of a refrigerator, and as a result, the angle passing through each opening. The present invention is to provide a double damper device to cool the seals efficiently for energy efficiency and to easily control the temperature of each seal.

In order to solve the above object, the present invention provides a driving unit, two cylindrical frame units disposed on both sides with the driving unit interposed therebetween, and opening and closing openings formed in the respective frame units by the driving force of the driving unit connected to the driving unit. In the double damper device having two opening and closing members for performing the operation, a step is formed between the flat portions of the two frame portions.

For this reason, the surface of both frame portions is a kind of labyrinth structure due to the step formed between the flat portions of the two frame portions. For example, even if a gap is generated between the double damper device and the heat insulating member, the creepage distance of the gap is caused. Lengthens. As a result, in the gap formed between the double damper device and the heat insulating member fitted to the double damper device, the cold air of one flow path or the like does not leak easily to the other flow path.

Further, in addition to the above-described invention, another step is provided at two positions on the boundary portions of the drive section and the two frame sections so that one side of the drive section becomes concave or convex with respect to the flat sections of the two frame sections. Therefore, the heat insulating member which divides two flow paths can be inserted reliably and closely_contact | adhered using the site | part formed in concave shape or convex shape. In addition, when the portion formed by the step is convex, the heat insulating member side formed of a member having a small strength such as foamed styrole can be formed in a concave shape. Will not.

Another invention is in addition to each of the above-described inventions, and the step is formed on a surface parallel to the direction in which the fluid passing through the opening flows. By arranging the steps so that the fluid flows in this way, the leakage from one flow path to the other flow path can be reliably blocked over a predetermined flow path length, and the fluid can flow efficiently.

In still another invention, in addition to each of the above-described inventions, a heat insulating member for blocking two flow paths into which two openings enter each other is fitted into the concave portion or the convex portion formed by the step. Therefore, the heat insulating member surely enters the concave portion or the convex portion, whereby the leakage of the fluid can be blocked more reliably.

In addition to each of the above-described inventions, the invention further includes a drive unit disposed between two frame portions such that one side of the drive portion is convex with respect to the flat portion of the frame portion, and the protrusion of the drive portion is arranged in a cavity in which the driving machine parts are not arranged. It is made into a hollow. Therefore, in addition to the above-described action of preventing the leakage of the fluid and preventing the breakage of the heat insulating member, the wiring for electricity supply can be provided using the cavity, or the cavity can be used as part of the heat insulating portion.

In addition to each of the above-described inventions, the invention further includes a driving unit disposed between two frame portions such that one surface of the driving portion is concave with respect to the flat portion of the frame portion, and a feeding member for supplying electricity to the driving portion in the recessed portion of the driving portion. Is placed. Therefore, in addition to the above-mentioned effect of preventing the leakage of the fluid, it is possible to wind the wiring by using the concave portion (depressed portion).

1 is a front view of a double damper device according to an embodiment of the present invention, in which the baffle on the left is in an open state and the baffle on the right is in a closed state.

2 is a partial cross-sectional view of the double damper device shown in FIG.

3 is a cross-sectional view taken along line III-III of FIG. 1;

4 is a view of the driving unit of the double damper device shown in FIG.

Fig. 5 is a diagram schematically showing a modification of the double damper device of the embodiment of the present invention.

6 is a view schematically showing another modification of the double damper device of the embodiment of the present invention.

Fig. 7 is a diagram schematically showing another modification of the double damper device of the embodiment of the present invention.

8 is a front view of a conventional double damper device, in which the left baffle is in an open state and the right baffle is in a closed state.

FIG. 9 is a IX-IX cross-sectional view of FIG. 8. FIG.

1 and 4, an embodiment of the double damper device of the present invention will be described. In addition, the double damper device of this embodiment is a motor damper device used in a refrigerator and driven by a motor.

As shown in Figs. 1 and 2, the double damper device 1 of the present embodiment has two resin frame parts 3 and 4 disposed on both sides with the driving part 2 and the driving part 2 interposed therebetween. And baffles 5 and 6, both ends of which are supported by the frame portions 3 and 4, respectively, and serve as opening / closing members which rotate by the driving force of the driving unit 2.

In addition, openings 31 and 41 are formed in the frames 3 and 4, respectively, and the openings 31 and 41 are opened and closed by operating the baffles 5 and 6 by the driving force of the driving unit 2. It is supposed to. These openings 31 and 41 are all in communication with the freezer compartment (not shown) of the refrigerator, but the opening 31 is the inlet of the cold air passage 7a to the refrigerating compartment, and the opening 41 of the cold air passage 7b to the vegetable compartment. It is attached to the refrigerator so as to be an entrance. Therefore, the baffles 5 and 6 serve as valves for temperature control of the different chambers respectively.

The double damper device 1 is disposed in the duct 9 of the refrigerator together with the heat insulating member 8 in a state of being fitted into the hole 8a of the heat insulating member 8. This heat insulating member 8 is for performing both the fluid separation of the freezer compartment side, the refrigerator compartment, and the vegetable compartment side of the duct 9, and the fluid separation of the flow passage 7a through the refrigeration chamber and the fluid passage 7b through the vegetable compartment.

The drive unit 2 is for rotating the two baffles 5 and 6 separately, and includes gears for internal driving, ie, stepping motors and gear wheels including two output shafts capable of individual operation (not shown). Is stored in a substantially rectangular case body 11 made of resin. The case body 11 is a cup-shaped member 12 by engaging the projections 13 and 13 formed in the cup-shaped member 12 with the hooks 15 and 15 formed in the lid-shaped member 14 as shown in FIG. ) And lid-shaped member 14 are integrated. The double damper device 1 of the present embodiment fits both side portions 16 and 17 of the drive portion 2 to the two frame portions 3 and 4, and the two frame portions 3 and 4 in this state. It is formed by screwing.

One frame portion 3 has a rectangular cylindrical outer frame 32, a blocking surface 33 disposed on the inner circumferential surface of the outer frame 32 so as to be orthogonal to the outer frame 32, and a blocking surface as shown in FIG. The opening 31 arrange | positioned at 33 and the cylinder part 34 formed so that the outer edge of the opening 31 may protrude to the both sides of the blocking surface 33 orthogonal to the blocking surface 33 may be comprised. The outer frame 32 has a contact surface 35 for contacting the side surface 16 of the drive unit 2, an opposing surface 36 which is a position opposed to the contact surface 35, these contact surfaces 35 and The connection surface 37a, 37b for connecting the opposing surface 36 is provided. An insertion hole 35a for inserting one of the supporting shafts 5a of the baffle 5 is disposed on the contact surface 35. On the opposing surface 36, a loosely fitted bottomed hole 36a capable of free rotation of the other axis 5b of the baffle 5 is disposed. Here, the connection surfaces 37a and 37b are flat portions.

By such a structure, the frame part 3 is made to contact the contact surface 35 to the drive part 2 in the state which protruded one support shaft 5a of the baffle 5 from the contact surface 35, and the protruding support shaft 5a is inserted into the indentation hole 16a formed in the side surface 16 of the drive part 2. The baffle 5 is thus connected to the drive unit 2. The tip end of the baffle 5 support shaft 5a is fitted into one output shaft (not shown) of the drive unit 2 in the inlet hole 16a. For this reason, the baffle 5 is rotated in the outer frame 32 of the frame part 3 while being supported by the frame part 3 by the driving force of the drive part 2.

The baffle 5 supported by the frame portion 3 is formed of a plate-like member which rotates with the pivot shafts 5a and 5b as the pivot center, and one side has a soft tape 5c (see Fig. 3). ). A locking portion 5d for locking one end of the coil spring 25 is disposed at a position away from the rotation point on one surface of the baffle 5. The other end of the coil spring 25 is fixed to the locking portion 34a disposed inside the cylinder portion 34 of the frame portion 3, and the baffle 5 is always opened by the bias force of the coil spring 25. It is taxed to the (31) side.

In addition, the other frame part 4 is disposed at a position symmetrical with one frame part 3 with the driving part 2 interposed therebetween, except for the configuration of the contact surface 45 with the driving part 2. It has the same configuration as (3). In addition, the baffle 6 rotatably supported by the frame portion 4 also has the same configuration as the baffle 5 described above.

On one side of the contact surface 45 of the other frame portion 4, a boss (not shown) to be inserted into the positioning hole 17b (see Fig. 4) disposed on the side surface 17 of the driving portion 2 is disposed. The support shaft 6a of one of the baffles 6 arranged symmetrically with the boss and the baffle 5 described above serves as a positioning member with respect to the drive unit 2 of the frame portion 4. The same positioning boss is also disposed in one frame portion 3.

On one side of the contact surface 45 of the other frame portion 4 formed as described above, as shown in FIGS. 2 and 3, the support column 48a of the screw insertion hole that extends toward the one frame portion 3 with the driving portion 2 interposed therebetween. 48b, 48c and 48d are arranged. Screw holes are formed at the tips of the support columns 48a, 48b, 48c, and 48d of the frame portion 4, respectively. Further, screw holes 38a, 38b, 38c and 38d are formed in the contact surface 35 of one frame portion 3. The screw holes and one frame of the support pillars 48a, 48b, 48c, and 48d on the other frame portion 4 side with the drive portion 2 fitted in both frames 3 and 4, respectively. Both frames 3 and 4 are fixed to both sides of the drive unit 2 by screwing the screw holes 38a, 38b, 38c, 38d formed in the contact surface 35 of 3).

In addition, two concave portions 11a, 11b, 11c, and 11d are formed on the outer periphery of the case body 11 constituting the drive unit 2 so as to enter inwardly as shown in FIG. These recessed portions 11a, 11b, 11c, and 11d move the support columns 48a, 48b, 48c, and 48d described above from one frame portion 4 to the other frame portion 3 side. It is a recess for inserting. In addition, the lead wire lead-out part 18 which draws out the lead wire 36 is formed in the vicinity of 11a which becomes one of four recesses.

The double damper device 1 of the present embodiment configured as described above has two steps β between the two openings 31 and 41 serving as the inlets of the two flow paths 7a and 7b as shown in FIG. Is formed to form a shape in which the two steps beta are recessed in a concave shape. In addition, the two steps beta are respectively attached to the driving part 2 and the two frame parts 3 by attaching the driving part 2 so as to form two steps β with respect to both the frame parts 3 and 4. It is formed at the boundary of 4). The two steps beta formed in this way pass through the openings 31 and 41 of the double damper device 1, one of the surfaces parallel to the fluid direction flowing through the flow paths a and 7b, that is, It is arrange | positioned at the surface X1 of the side provided with the lead wire lead-out part 18 of the drive part 2. As shown in FIG. As a result, one side of the driving unit 2 on the side of the surface X1 has a concave shape with respect to the flat portions 37b and 47b of the outer frame 32 and 42 of the two frames 3 and 4). do.

And the fitting convex part 8b of the heat insulating member 8 is fitted in the recessed part (concave part) formed by these two steps (beta). That is, the fitting convex part 8b formed in the hole part 8a of the heat insulation member 8 is protruded inward, and the concave part of the double damper apparatus 1 is fitted into this fitting convex part 8b, and it doubles. The damper device 1 is fitted in the hole 8a of the heat insulating member 8. As a result, a so-called labyrinth structure is constituted, and the double damper device 1 and the heat insulating member are formed in the recessed portion with the creepage distance of the surface where the heat insulating member 8 and the double damper device 1 contact is flat. It becomes longer with respect to the creepage distance in the case where 8) is contacted. Therefore, outflow of cold air etc. is inhibited on the surface X1 side of the formation side of the above-mentioned recessed part, and cold air etc. of one flow path do not leak easily to the other flow path.

That is, even if a gap is formed in the contact surface between the heat insulating member 8 and the double damper device 1 formed of a rigid body, the other opening 41 or (or the other opening 41 or (41) side along the gap is formed. 31) can be prevented from leaking (leakage).

In addition, the above-described embodiment is an example of a suitable embodiment of the present invention, but is not limited thereto, and various modifications may be made without departing from the gist of the present invention. For example, in the double damper device 1 of the above-described embodiment, a recess is formed by arranging two steps β on the surface X1 side of the side where the lead wire lead-out portion 18 is provided, whereby Although it is comprised so that leakage (leakage) is prevented, only one step (beta) may be sufficient. That is, it is not necessary to make the recessed part only by providing only the step (beta) between the frame parts 3 and 4.

In addition, when the fitting convex part 8b which fits into the recessed part of the double damper device 1 is not arrange | positioned at the heat insulating member 8 side, as shown in FIG. 5, the gap | interval between the drive part 2 and the heat insulating member 8 is carried out. G) is formed, but in this case, the contact surfaces 35 and 45 of both the frame members 3 and 4 are projected to the heat insulating material 8 side, and the tip thereof is a rib for contacting the heat insulating material 8 ( By forming 35d) 45d, leakage of cold air in this gap G part can be prevented. If the gap G portion is used to arrange an electric supply member such as a lead wire, there is no need to arrange a recess passing through the lead wire on the heat insulating material side.

The ribs may be arranged in parallel with the structure in which the fitting convex portion 8b of the heat insulating member 8 is fitted to the concave portion of the double damper device 1 described above.

In the above-described double damper device 1, a recess is formed only on the surface X1 side, and cold air leakage (leakage) is prevented only at this portion. However, as shown in FIG. 6, two double damper devices 1 are also provided on the surface X2 opposite to the surface X1. It is good also as a structure which arrange | positions step (beta ') and prevents the outflow of cold air on the surface X2 side similarly to the surface X1 side. The step (beta ') may also be one or three or more to form a complex labyrinth structure.

In addition, as in the above-described embodiment, the double damper device 1 has a concave portion formed only on the surface X1 side so that the surface on the side opposite to the surface X1 is in a straight line shape, and at the same time, the hole 8a of the heat insulating member 8 Is configured to have the same shape as that of the double damper device 1, that is, the fitting portion 8b is provided in the hole 8a, the operator incorrectly inserts the double damper device 1 into the heat insulating member 8. It can also have the effect of avoiding mistakes.

In other words, the double damper device 1 according to the above-described embodiment is apparent from FIG. 1 because it is easy to distinguish the front surface (the side with the baffles 5 and 6) from the inner surface, but is formed symmetrically. The distinction is difficult at a glance. Because of this, there may be a risk of inverting the left and right. If the right and left are inserted into the heat insulating member 8, the baffle on the reverse side is opened and closed under the control of a microcomputer or the like, and a control problem occurs. However, as described above, if one side is flat and the other side is formed with a concave portion or convex portion, the case of incorrect insertion when fitting does not occur.

Further, by adopting a configuration in which one side is a flat surface, the position of the holes (insertion holes 35a and 45a in the above-described embodiment) into which the supporting shafts 5a and 6a of the baffles 5 and 6 are inserted is also determined. It becomes possible to form in the vicinity of the linear surface side, and as a result, the ratio of the area of the opening 31 and 41 can be enlarged with respect to the area of the whole of the frame part 3 and 4, and it is effective to distribute | circulate cold air, etc. Can be.

In the double damper device 1 according to the embodiment of the present invention, the step β is arranged on the surface X1 which is parallel to the direction in which the cold air flows. It may be arranged. In this case, the double damper device 1 has a labyrinth structure in the front and rear directions, that is, one passing through the duct communicating with the freezer compartment and the other passing through the flow passage communicating with each other chamber, so that the cold air in one freezing compartment is better in the other flow passage. It won't leak.

In addition, in the above-described double damper device 1, by arranging two steps β, one side of the drive unit 2 is configured to be concave with respect to one side of both frame units 3 and 4, but with reference to FIGS. Similarly, the step 2 is formed by attaching the driving unit 2 to both the frame units 3 and 4 so that one side of the driving unit 2 is concave with respect to the two frames 3 and 4. In addition, it is good also as a labyrinth structure by this site | part and the heat insulating member 8.

In addition, when the double damper device 1 of such a shape is actually formed, the internal mechanism of the drive unit 2 and the two frames 3 and 4 are used in the above-described embodiment, The inside of the part which protrudes from the both frame parts 3 and 4 of the drive part 2 may be made into a cavity part only by the dimension enlarged. By configuring in this way, the drive part 2 can be made convex with respect to both the frames 3 and 4 only by changing the dimension of the case body 11 of the above-mentioned embodiment. In addition, an electric supply member such as a lead wire can be arranged using a cavity in the case body 11, or the cavity itself can be used as a heat insulating part.

In the present embodiment, the double damper device 1 is described as being inserted into the duct 9 of the refrigerator. However, the damper device 1 is not limited to the refrigerator but may be attached to another device.

As described above, in the double damper device of the present invention, a driving part, two frame parts disposed on both sides with the driving part interposed therebetween, and connected to the driving part to open and close the openings formed in the respective frame parts by the driving force of the driving part, respectively. It has two opening / closing members which perform an operation | movement, and the step | step difference is formed between the flat parts of two frame parts. For this reason, when the device is inserted into a heat insulating member or the like, the part becomes a so-called labyrinth structure, and the creepage distance of a predetermined surface (part of the contact surface with the heat insulating member or the like) between the two frame portions becomes long. As a result, leakage of fluid such as cold air in the gap formed between the double damper device and the heat insulating member can be prevented, and each chamber passing through each opening can be cooled for good energy efficiency, and the temperature management of each chamber can be easily performed. You can do it. The step may be used to arrange an electric supply member such as a lead wire, and the step may be used as a display when the double damper device is attached to the apparatus side.

Claims (6)

A driving part, two cylindrical frame parts disposed on both sides with the driving part interposed therebetween, and two opening / closing parts connected to the driving part to open and close openings formed in the respective frame parts by the driving force of the driving part. A double damper device having a member, wherein a step is formed between the flat portions of the two frame portions. The method of claim 1, The step is provided with two double dampers, characterized in that two surfaces are formed at respective boundary portions of the drive section and the two frame sections so that one surface of the drive section is concave or convex with respect to the flat sections of the two frame sections. . The method of claim 1, And the step is formed on a surface parallel to the flow direction of the fluid passing through the opening. The method of claim 1, And a heat insulating member for blocking two flow paths into which the two openings respectively enter the concave portion or the convex portion formed by the step. The method of claim 1, The driving portion is disposed between the two frame portions so that one surface of the driving portion is convex with respect to the flat portion of the frame portion, and the protruding portion of the driving portion is a cavity in which no driving machine parts are arranged. Double damper device. The method of claim 1, The driving part is disposed between the two frame parts such that one surface of the driving part is concave with respect to the flat part of the frame part, and a feeding member for supplying electricity to the driving part is disposed at the recessed part of the driving part. Double damper device characterized in that.